JP2019106921A - Combine - Google Patents

Abstract

To provide a combine capable of smoothly, quickly, and separately stopping a feed chain clutch in accordance with the lifting of a reaping part, and stopping the feed chain clutch independently.SOLUTION: A combine includes: an operation part 65 capable of performing a switching operation between an on-position corresponding to a transmission state and an off-position corresponding to a cut-off state; a command stop operation mechanism 66 for switching a feed chain clutch to the cut-off state based on an artificial stop command; and an interlocking stop operation mechanism 109 for switching the feed chain clutch to the cut-off state when a reaping part is lifted to a predetermined height position or higher, and is configured so that, when one of the command stop operation mechanism 66 and the interlocking stop operation mechanism 109 performs switching to the cut-off state, the operation force of the one mechanism is not transmitted to the other mechanism.SELECTED DRAWING: Figure 7

Description

  The present invention relates to a combine having a feed chain for conveying a reaper to a threshing device, and configured to be able to interrupt power to the feed chain by means of a feed chain clutch.

  In this type of combine, there has conventionally been provided a cam type clutch operating device driven by an electric motor in order to turn on and off the feed chain clutch. In other words, a clutch equipped with a cam mechanism that is turned by an electric motor according to the working conditions, such as when the reaper rises to a predetermined height position or at the time of a pillow squeezing operation for threshing hand-harvested grain The feed chain clutch is configured to be switched between the transmission state and the disconnection state by the operating device. Then, when switching the feed chain clutch to the disconnected state, the cam mechanism is operated to the operation position corresponding to the reaping and feeding stop state in which the operation of the reaper is stopped and the operation of the feed chain is stopped. For example, refer to Patent Document 1).

JP, 2004-97052, A

  In the above-described conventional configuration, for example, when it is desired to quickly stop the feed chain when performing the pillow squeezing operation, in order to switch the feed chain clutch to the disconnection state, the cam mechanism is in the reaping transport stop state It is necessary to operate the cam mechanism to the operation position corresponding to the above, which is disadvantageous in that it takes time.

  Therefore, it has been desired that the feed chain clutch be stopped with the rise of the reaper and the feed chain clutch be independently stopped separately and smoothly and quickly.

The characteristic configuration of the combine according to the present invention is
Ascent and descent reaping section which reaps cropped rice straw,
A feed chain for transporting the reaper to the threshing device;
A feed chain clutch switchable between a transmission state for transmitting power to the feed chain and a disconnection state for cutting off the power to the feed chain;
An operating unit capable of switching between an on position corresponding to the transmission state of the feed chain clutch and a off position corresponding to the disconnection state;
A command stop operation mechanism that switches the feed chain clutch to the disengaged state by operating the operation unit based on an artificial stop command;
An interlock stop operation mechanism that operates the operation unit to switch the feed chain clutch to the disengaged state when the reaper is raised to a predetermined height position or higher;
A first buffer mechanism that links the command stop operation mechanism to the operation unit;
A second buffer mechanism linking the interlock stop operation mechanism to the operation unit;
When one of the first stop mechanism and the second stop mechanism performs switching to the shutoff state, the first buffer mechanism and the second buffer mechanism are configured to control the operating force of the one mechanism, The point is configured not to transmit to the other mechanism of the command stop operation mechanism and the interlocked stop operation mechanism.

  According to the present invention, when the reaper rises to a predetermined height position during the reaper operation, the interlock stop operation mechanism operates the operation portion to switch the feed chain clutch to the disconnected state. On the other hand, for example, when the reaper is stopped and the feed chain is operated, etc., if there is an artificial stop command, the command stop operation mechanism operates the operation unit to cut off the feed chain clutch. Switch to As described above, in either case, the feed chain clutch can be quickly switched to the disengaged state by operating the operation unit.

  The command stop operation mechanism and the interlocking stop operation mechanism are linked with the operation unit via the first buffer mechanism and the second buffer mechanism buffer mechanism respectively, and when one of them performs switching to the blocking state Can smoothly perform the switching operation without affecting the operation of the other operation mechanism.

  Therefore, when the reaper rises to a predetermined height position, switching the feed chain clutch to the disengaged state and stopping the feed chain clutch when operating alone are performed smoothly and quickly for each of them. It became possible.

In the present invention, the operation portion is provided with an operation member for switching the feed chain clutch by a rotation operation, and an arm rotatable around the rotation axis of the operation member with the operation member.
The first shock absorbing mechanism links the arm and the command stop operation mechanism, and the second shock absorbing mechanism is a portion different from the portion where the first shock absorbing mechanism is linked among the arms and the interlock It is preferable to be linked with the stop operation mechanism.

  According to this configuration, the operation unit is configured to have the arm and switch the feed chain clutch by the rotation operation, so that the operation can be performed more smoothly than, for example, the configuration to switch the feed chain clutch by the slide operation. Also, since the first buffer mechanism and the second buffer mechanism are linked to different parts of the arm, they can be linked with a simple structure without interfering with each other.

In the present invention, the command stop operation mechanism and the interlock stop operation mechanism are configured to push and move the arm in a contact state so as to rotate in a predetermined direction to switch the feed chain clutch.
The first buffer mechanism separates the command stop operation mechanism from the arm when the switching operation is performed by the interlock stop operation mechanism, and transmits the operation force of the interlock stop operation mechanism to the command stop operation mechanism. Without
When the switching operation is performed by the command stop operation mechanism, the second buffer mechanism separates the interlock stop operation mechanism from the arm, and transmits the operation force of the command stop operation mechanism to the interlock stop operation mechanism. It is preferable not to do it.

  According to this configuration, the command stop operation mechanism and the interlock stop operation mechanism both push and move in the abutting state so as to turn in the same predetermined direction, and operate the arm. That is, the feed chain clutch is switched to the disengaged state by turning the operating portion in the predetermined direction. When one of the command stop operation mechanism and the interlocked stop operation mechanism operates the arm, the other is separated from the corresponding arm and the operation force of the corresponding operation mechanism is not transmitted to the other operation mechanism, so both operations The mechanisms are capable of smoothly performing switching operations without being disturbed with each other.

  Since the operation member is operated by contacting the arm in this way and the operation force is not transmitted to the other side by separating from the arm, the first buffer mechanism and the second buffer mechanism are supported by a simple structure. it can.

In the present invention, a transmission shaft for transmitting power to the feed chain is provided,
The feed chain clutch is of a meshing type having a pair of clutch members that can be meshed oppositely on the transmission shaft,
It is preferable that the operation portion be provided with a shift fork type shifter member capable of disengaging the pair of clutch members.

  According to this configuration, when the command stop operation mechanism or the interlock stop operation mechanism is operated, the shifter member moves one of the pair of clutch members toward the meshing release side, and the feed chain clutch is disengaged. It changes. When the operation of the command stop operation mechanism or the interlock stop operation mechanism is released, the operation member is switched to the in position by the biasing force of the biasing mechanism.

  As described above, since the clutch member in the meshing type is shifted by the shift member by the shift member, the switching to the disconnection state can be performed quickly.

  In the present invention, there is provided a braking mechanism for applying a braking force to a member of the pair of clutch members which is moved along the transmission shaft as the operation portion is operated to the off position. It is preferable to be provided.

  According to this configuration, the transmission shaft is braked by the braking mechanism as the operation portion is operated to the off position and the feed chain clutch is switched to the disconnection state. Since the power transmission to the feed chain is cut off and the braking force is applied, it is possible to prevent the rotation due to the inertial force and to more quickly and reliably deactivate the feed chain.

It is a whole side view of a combine. It is a whole top view of a combine. It is a vertical back view of a threshing apparatus. It is a vertical rear view of the threshing apparatus of the state switched to the raising position. It is a side view of a threshing apparatus. It is sectional drawing of the transmission mechanism with respect to a feed chain. It is a side view which shows the interruption | blocking switching operation mechanism. It is a top view which shows the interruption | blocking switching operation mechanism in a transmission state. It is a top view which shows the interruption | blocking switching operation mechanism in the state switched to the interruption | blocking state by the instruction | command stop operation mechanism. It is a top view which shows the interruption | blocking switching operation mechanism in the state switched to the interruption | blocking state by the interlocking stop operation mechanism. It is a side view showing an interlocking stop operation mechanism. It is a control block diagram.

  Hereinafter, an embodiment of a combine according to the present invention will be described based on the drawings.

〔overall structure〕
As shown in FIG. 1 and FIG. 2, the combine according to the present invention is provided with a reaper 3 for reaping planted cereals at the front of a traveling machine body 2 self-propelled by a pair of left and right crawler traveling devices 1 and 1 ing. On the front right side of the traveling vehicle 2, a driving unit 5 whose periphery is covered by a cabin 4 is provided. Behind the operation unit 5, a threshing device 6 for threshing the grain which has been cut by the mowing portion 3 and a grain tank 7 for storing grains obtained by the threshing process are arranged in a lateral direction. It is deployed in the state. Below the driver's seat 8 in the driver 5, an engine 9 is provided as a power source for driving each part of the vehicle.

  In this embodiment, when defining the longitudinal direction of the vehicle, it is defined along the traveling direction of the vehicle in the working state, and when defining the left-right direction of the vehicle, left and right are defined in the state viewed in the traveling direction of the vehicle. . That is, the direction shown by the code (F) in FIGS. 1 and 2 is the machine front side, and the direction shown by the code (B) in FIGS. 1 and 2 is the machine rear side. The direction indicated by the symbol (L) in FIG. 2 is the left side of the machine, and the direction indicated by the symbol (R) in FIG. 2 is the right side of the machine.

  The reaper 3 is a branching tool 10 for dividing the original plant of the planted rice straw to be harvested into a draft, a plurality of inducing devices 11 for causing the cropped planted rice straw to be in a vertical posture, and an induced planting A clipper-type reaper 12 for cutting the origin of the rice husk, and a conveying device 13 which conveys the retried grain rice yard to the threshing device 6 by transporting it backward while changing its posture so as to gradually fall from horizontal to vertical. Etc. The upper side of the transport device 13 is covered by a dustproof cover 14.

  The left side of the threshing device 6 is provided with a feed chain 15 for conveying the harvested grain to the threshing device 6, and a clamping rail 16 provided opposite to the upper side thereof. At the rear of the threshing device 6, a eliminator 17 is provided which cuts off the sluice from the threshing device 6. The grain tank 7 is provided with a grain discharging device 18 for discharging the grain stored in the grain tank 7 to the outside of the machine.

Threshing device
The threshing device 6 performs threshing processing on the tip end side of the reaper in the sipping chamber 19 while conveying the original side of the reaper with a feed chain 15 and a holding rail 16. A threshing cylinder 20 is provided in the throttling chamber 19. As shown in FIG. 3, the threshing cylinder 20 is rotatable around a rotational axis Y1 extending in the longitudinal direction of the machine. A net 21 is provided below the threshing drum 20. A dust collecting fan 22 for discharging dust to the outside is provided behind the processing chamber 19 (see FIG. 5). The left outside of the threshing device 6 is covered by an exterior cover 23.

  As shown in FIG. 5, at the lower part of the threshing device 6, a sorting unit 24 is provided for sorting the threshed treated material leaked from the net 21 into grains, second-pieces, waste straw scraps and the like. The sorting unit 24 is a swing sorting device 25 for sorting while sorting the objects to be sorted to the rear of the machine body, a gourd 26 for blowing the sorting air to the swing sorting device 25, a grain of the first one Etc.) and a second collection unit 28 for collecting second-class grains (grains with a branch).

  The threshing device 6 is provided with an upper side threshing split body 30 having a threshing drum 20 and a rail base 29 supporting the holding rails 16, and the upper side threshing split body 30 is provided around the longitudinal axis Y2. It is configured to be able to swing up and down between a normal working position on the lower side and a rising position that has swung upward.

  To add to the description, wall portions 31 are provided at the front end portion and the rear end portion of the handling chamber 19, respectively. As shown in FIG. 3, the wall portion 31 includes a movable wall 32 and a fixed wall 33. A threshing cylinder 20 is rotatably supported on the movable wall 32 via a bearing member 34. A connecting arm 35 for connecting the movable wall 32 and the fixed wall 33 is provided. The movable wall 32 is supported by the fixed wall 33 so as to be vertically pivotable around an axis Y2 along the longitudinal direction of the machine body via the connection arm 35.

  A rectangular tubular front-to-back frame body 36 is bridged and connected over upper portions on the left side (feed chain 15 side) of the movable walls 32 on the front and rear sides. A rail base 29 is supported over the left lower portions of the movable walls 32 on the front and rear sides. A top plate 37 is provided over the upper ends of the movable walls 32 on both the front and rear sides, and the top plate 37 is fixedly attached to the movable walls 32 on both the front and rear sides.

  Accordingly, the threshing drum 20, the rail base 29, the top plate 37, the front-rear direction frame body 36, and the like are integrally connected to form the upper side threshing split body 30.

  An electric hydraulic cylinder 38 as an elevating actuator capable of rocking operation of the upper side threshing divided body 30 between the normal work position and the raised position is provided. The electro-hydraulic cylinder 38 is connected across the connecting arm 35 and the fixed wall 33 in the rear wall 31. The electric hydraulic cylinder 38 includes a hydraulic cylinder 39, a hydraulic pump 40 for supplying hydraulic oil to the hydraulic cylinder 39, an electric motor 41 for driving the hydraulic pump 40, a hydraulic unit (not shown) for controlling the hydraulic cylinder 39, etc. It is configured. By supplying electric power to the electric motor 41, the hydraulic cylinder 39 is operated to extend and contract, and the upper side threshing split body 30 is configured to be able to operate to swing up and down.

  At the rocking fulcrum position of the upper side threshing division 30, a height sensor 42 of a potentiometer type for detecting the vertical rocking position of the upper side threshing division 30 is provided. Further, as shown in FIG. 12, a control device 43 for controlling the operation of the motor-driven hydraulic cylinder 38 is provided. The controller 43 is configured to include a microcomputer.

  As shown in FIG. 12, a lift switch 44 as an opening command operation tool for commanding a lift operation, a lowering switch 46 for commanding a descent operation, and a level setter 45 for commanding any of a plurality of positions are provided. ing. The raising switch 44, the lowering switch 46, and the level setter 45 are provided, for example, in the operation unit 5.

  The control device 43 is configured to control the operation of the electrohydraulic cylinder 38 so as to raise the upper side threshing segment 30 to the maintenance raising position for opening the throttling chamber 19 based on the operation of the raising switch 44. ing. The raised position for maintenance is a position at which the handling chamber 19 is opened so that the cleaning operation of the inside of the handling chamber 19 can be performed. The level setter 45 can set any one of a plurality of stages as the maintenance elevated position.

  When the raising switch 44 is operated, the control device 43 raises the upper side threshing division 30 until the height detected by the height sensor 42 reaches the setting position set by the level setting device 45. Further, the control device 43 controls the operation of the electrohydraulic cylinder 38 so as to lower the upper side threshing split body 30 to the normal work position when the lowering switch 46 is operated.

  A lock mechanism 130 is provided to hold the upper side threshing segment 30 in the normal working position. The lock mechanism 130 includes a pair of front and rear hook plates 131 and a pair of front and rear locking pins 132. A hook plate 131 is supported swingably around a swing axis Y3 extending in the longitudinal direction of the machine on each of the front and rear wall portions 31. A hook portion 131 a that can be engaged with the locking pin 132 is provided at the tip of the hook plate 131. When the hook portion 131 a engages with the locking pin 132, the upper side threshing split body 30 is held in position. When the engagement of the hook portion 131a with the locking pin 132 is released, it can be pivoted upward. A motor M that swings and drives a pair of front and rear hook plates 131 is supported on the rear surface of the rear wall 31. The motor M pivots the pair of front and rear hook plates 131 to the engagement side and the engagement release side.

[Transmission structure for feed chain]
As shown in FIG. 5, the feed chain 15 is wound around a drive sprocket 47 located on the rear side and a driven sprocket 48 located on the front side. A feed chain clutch 49 is provided which can be switched between a transmission state for transmitting power to the feed chain 15 and a cutoff state for cutting off the power to the feed chain 15. The feed chain clutch 49 is provided on a drive shaft 50 (an example of a transmission shaft) that rotatably supports the drive sprocket 47.

  As shown in FIG. 6, the power from the engine 9 is transmitted to the feed chain clutch 49 via the transmission case 54. More specifically, the power from the engine 9 is transmitted to the relay shaft 53 via the transmission belt 51 and the input pulley 52, and from the relay shaft 53 via the gears 55 and 56, the rotation shaft of the dust collecting fan 22. It is transmitted to 57. Further, the power from the rotation shaft 57 is transmitted to the drive gear 59 externally extrapolated to the drive shaft 50 via the two-stage reduction gear mechanism 58. The power from the drive gear 59 is transmitted to the drive sprocket 47 of the feed chain 15 so as to be able to be interrupted via the feed chain clutch 49.

  The driven side shift member 60 is externally fitted with splines on the drive shaft 50 so as to be integrally rotatable and movable in the axial direction. On the surface of the drive gear 59 on the side facing the driven shift member 60, a drive side engaging portion 61 formed of a claw portion for engaging is formed. On the surface of the driven shift member 60 on the side facing the drive gear 59, a driven meshing portion 62 formed of a meshing claw portion is formed. The feed chain clutch 49 is composed of a drive side meshing portion 61 and a driven side meshing portion 62. The power from the reduction gear mechanism 58 is transmitted to the drive gear 59, and the power from the drive gear 59 is transmitted to the feed chain 15 via the drive shaft 50 and the drive sprocket 47 via the feed chain clutch 49. Accordingly, the drive gear 59 and the driven shift member 60 correspond to a pair of clutch members.

  In the feed chain clutch 49, the driven shift member 60 is on the drive sprocket 47 side in a transmission state in which the driven shift member 60 moves toward the drive gear 59 and the drive meshing portion 61 and the driven meshing portion 62 mesh with each other. , And the meshing portion 61 on the drive side and the meshing portion 62 on the driven side can be switched to the blocking state in which the meshing is released. A coil spring 63 for moving and urging the driven shift member 60 toward the drive gear 59 is externally inserted on the drive shaft 50. That is, the driven shift member 60 is biased toward the clutch engagement position.

  A multi-plate friction braking mechanism 64 is provided at a position on the drive sprocket 47 side with respect to the driven shift member 60 in the drive shaft 50. The braking mechanism 64 is configured to apply a braking force to the driven shift member 60 as the driven shift member 60 is operated to the off position by an external operation force as described later.

Next, the operation structure of the feed chain clutch 49 will be described.
The feed chain clutch is operated by operating the operation unit 65 based on the operation unit 65 that can be switched to the on position corresponding to the transmission state of the feed chain clutch 49 and the off position corresponding to the disconnection state, and an artificial stop command. A command stop operation mechanism 66 for switching 49 to the shutoff state is provided. Therefore, the operating portion 65 and the command stop operation mechanism 66 constitute a shutoff switching operation mechanism 67 capable of switching the feed chain clutch 49 to the shutoff state.

[Operation part]
The operation unit 65 will be described.
As shown in FIG. 6 to FIG. 8, in the operation portion 65, a shift member 68 as a shift fork type operation member capable of separating the drive gear 59 and the driven shift member 60 and rotation of the shifter member 68 A clutch operating arm (corresponding to an arm in the present invention) 69 is provided around the axis so as to be integrally rotatable with the shifter member 68. The shifter member 68 is housed in the transmission case 54. Shifter member 68 has a support shaft portion 68 a supported by transmission case 54 so as to be rotatable about axis Y 4 along the upward and downward inclination direction, and an engagement operation portion 68 b engaged with the outer peripheral portion of driven shift member 60. And.

  A clutch operation arm 69 is coupled to a portion of the support shaft portion 68 a protruding outward of the transmission case 54 so as to be integrally rotatable. The clutch operating arm 69 is formed in the shape of a linearly extending band plate, and the longitudinal middle portion is connected to the support shaft portion 68 a. The clutch operation arm 69 is provided so that the longitudinal direction substantially follows the side wall 6A of the threshing device 6, and the installation space in the left-right direction is made compact.

  Since the driven side shift member 60 is moved and urged toward the drive gear 59 by the urging force of the coil spring 63, the clutch operation arm 69 is rotationally urged to the input position (transmission state). When the clutch operation arm 69 is turned in a predetermined direction, specifically, to the left in a plan view shown in FIG. 8 by the operation force from the outside, the engagement operation portion 68b engages the driven shift member 60. It is configured to be able to shift in the direction of release.

[Command stop operation mechanism]
Next, the command stop operation mechanism 66 will be described.
As shown in FIGS. 7 and 8, in the command stop operation mechanism 66, the cut-off coil spring 70 as an urging mechanism for urging the operation unit 65 to switch to the off position and the operation unit 65 in the entering position The position holding mechanism 71 to hold, the linkage mechanism 72 that links the position holding mechanism 71 with the operation unit 65, and receives an urging force by the blocking coil spring 70, position holding of the operation unit 65 at the entering position by the position holding mechanism 71 A release mechanism 73 and the like are provided. The blocking coil spring 70 has a biasing force that is larger than the biasing force of the coil spring 63 that biases the driven shift member 60 toward the clutch on position.

The linkage mechanism 72 will be described.
As shown in FIGS. 7 and 8, the linking mechanism 72 links the position holding mechanism 71 so as to hold the operation unit 65 in the in position, and when the position holding is released by the release mechanism 73, the blocking coil spring The clutch operating arm 69 is pressed by the biasing force of 70.

  The linkage mechanism 72 is provided with a linear horizontal link 74 that can slide in the horizontal direction, and a pressing link 75 that presses the clutch operating arm 69 by the sliding movement of the horizontal link 74. The pressing link 75 is linked to one end of the horizontal link 74, and the position holding mechanism 71 is linked to the other end of the horizontal link 74.

  The horizontal link 74 is provided to extend in the front-rear direction along the side wall 6A of the threshing device 6. A groove-like guide member 76 slidably supporting the horizontal link 74 in the front-rear direction is provided. The guide member 76 is fixed to the side wall 6A of the threshing device 6. Support shafts 77a and 77b penetrating in the vertical direction are fixedly attached to both sides in the longitudinal direction (longitudinal direction) of the horizontal link 74, respectively. Guide rollers 78 are provided at lower portions of the support shafts 77a and 77b on the front and rear sides, respectively. The guide roller 78 is located inside the guide member 76 and guides movement while rolling the inner surface of the guide member 76. The end of the pressing link 75 is pivotally connected to the top of the front support shaft 77a. The end of the position holding mechanism 71 is pivotally connected to an upper portion of the rear side support shaft 77b.

  The pressing link 75 is provided with three pressing arms 80, 81, 82 that can rotate integrally with the upper and lower pivoting support shaft 79. The rotation support shaft 79 is supported rotatably around the vertical axis X1 by a boss 83 fixed to the side wall 6A of the threshing device 6. One end of a blocking coil spring 70 is engaged with the swinging end of the first pressing arm 80. The swinging end of the second pressing arm 81 is provided with a command stop operating pin 84 that presses the clutch operating arm 69. A vertically oriented connecting shaft 85 is provided at the swinging end of the third pressing arm 82, and a boss 87 provided at one end of the interlocking link 86 with respect to the connecting shaft 85 is rotatably connected. ing. The boss portion 88 on the other end side of the interlocking link 86 is rotatably coupled to a support shaft 77 on the front side of the horizontal link 74.

  As shown in FIG. 8, when the first pressing arm 80 is rocked forward by the biasing force of the blocking coil spring 70, the command stopping operation pin 84 provided on the second pressing arm 81 is a clutch. A force acts in the direction of pressing the operation arm 69, and a force acts so that the third pressing arm 82 presses the support shaft 77 on the front side of the horizontal link 74 in the diagonal right direction. The pushing operation force causes the horizontal link 74 to slide rearward.

  However, the horizontal link 74 is prevented from moving rearward by the position holding mechanism 71 and held in the front slide position. In the position holding state, the command stop operation pin 84 does not push the clutch operation arm 69, and the clutch operation arm 69 is held at the on position.

The position holding mechanism 71 will be described.
As shown in FIGS. 7 and 8, the position holding mechanism 71 has the horizontal link 74 on which the force is applied to slide rearward by the biasing force of the blocking coil spring 70 as described above. And hold the clutch operating arm 69 in the in position. The position holding mechanism 71 includes a first holding arm 89 coupled to the rear side of the horizontal link 74 and a second holding arm 90 coupled to the release mechanism 73 side.

  A boss 91 is provided at one end of the first holding arm 89, and the boss 91 is swingably connected to a support shaft 77b on the rear side of the horizontal link 74 around the vertical axis X2. A boss 92 is provided at the other end of the first holding arm 89, and the boss 92 is connected to a connecting shaft 93 provided at one end of the second holding arm 90 so as to be relatively swingable. Between the first holding arm 89 and the second holding arm 90, a spring 94 for biasing the first holding arm 89 and the second holding arm 90 to bend forward and swing is provided. There is.

  A support shaft 96 is supported in a fixed position on a bracket 95 fixed to the side wall 6A of the threshing device 6. At the other end of the second holding arm 90, a boss portion 97, which is rotatably fitted on the support shaft 96, is integrally provided. The boss 97 is integrally provided with a connection arm 98 to which the release mechanism 73 is connected.

  The second holding arm 90 is provided with a contact control portion 99 that contacts the end edge of the first holding arm 89 to limit relative swing to the front side. The pivot connection point X3 between the first holding arm 89 and the second holding arm 90 is the rocking axis X2 at one end of the first holding arm 89 and the rocking axis at the other end of the second holding arm 90. At a position slightly closer to the front than the virtual line connecting X4, contact control portion 99 contacts the end edge of first holding arm 89, and bending and swinging further to the front side occurs. It is regulated. In the state in which the relative swing to the front side is restricted by the contact regulation part 99, the position of the horizontal link 74 biased to move backward is regulated and the position holding state is established.

The release mechanism 73 will be described.
As shown in FIGS. 7 and 8, in the release mechanism 73, an electric motor for blocking switching (hereinafter referred to as a blocking motor) 100 as an actuator, and the blocking motor 100 and the position holding mechanism 71 are linked. A release operation wire 101 as a wire member and a potentiometer 102 for detecting an operation amount of the shutoff motor 100 are provided. The blocking motor 100 and the potentiometer 102 are attached to a mounting plate 103 supported on the side wall 6A of the threshing device 6.

  The first motor arm 104 and the second motor arm 105 are coupled to the left-right oriented output shaft 100 a of the blocking motor 100 so as to be integrally rotatable. One end of the release operation wire 101 is connected to the connection arm 98, and the other end is connected to the first motor arm 104. When the shutoff motor 100 operates to turn the first motor arm 104, the release operation wire 101 is pulled and the contact holding state of the second holding arm 90 with the first holding arm 89 is restricted. It can be rocked to the side to be released.

  The release operation wire 101 includes an inner wire 101a and an outer wire 101b. Both ends of the outer wire 101b are supported by wire stays 106a and 106b. One end of the inner wire 101 a is connected to the connection arm 98. The other end of the inner wire 101 a is connected to the first motor arm 104.

  The potentiometer 102 is provided with a detection arm 107 so as to be able to swing. When the second motor arm 105 swings, it abuts on the contact portion 107a provided on the detection arm 107, and the detection arm 107 swings integrally to detect the swing angle of the second motor arm 105. can do. The swing angle of the second motor arm 105 corresponds to the amount of pull operation of the release operation wire 101 by the blocking motor 100.

  As shown in FIG. 1, a stop switch 108 as a stop command operation tool that can be manually pressed and operated from the outer side of the machine is located in the outer cover 23 of the threshing device 6 near the transport start end of the feed chain 15. It is provided. The release mechanism 73 is configured to execute the release operation based on the operation of the stop switch 108. The control operation of the control device 43 based on the operation of the stop switch 108 will be described later.

  When the release operation wire 101 is pulled, the second holding arm 90 swings, and the pivotal connection point X3 between the first holding arm 89 and the second holding arm 90 swings one end of the first holding arm 89. If the first holding arm 89 and the second holding arm 90 are located on the rear side when the moving axis X2 and the swing line X4 at the other end of the second holding arm 90 are located on the rear side It bends, and the sliding movement to the rear side of the horizontal link 74 is permitted. A force acts on the horizontal link 74 in the direction of moving backward by the biasing force of the blocking coil spring 70, so if the pivot connection point X3 slightly exceeds the imaginary line (dead point) to the rear side , The horizontal link 74 moves backward quickly. As a result, the position holding by the position holding mechanism 71 is released.

  When the position holding by the position holding mechanism 71 is released, the second pressing arm 81, that is, the command stopping operation pin 84 swings in the direction of pressing the clutch operating arm 69. As a result, the shifter member 68 is rotated to shift the driven shift member 60 to switch the feed chain clutch 49 to the disengaged state.

  The driven shift member 60 is switched to the blocking state, and is pressed by the braking mechanism 64 by the biasing force of the blocking coil spring 70 to apply the braking force. The rotation due to the inertial force of the feed chain 15 can be suppressed and the stop can be made quickly. As described above, when the feed chain clutch 49 is stopped by the command stop operation mechanism 66, the stop state is maintained until the position holding mechanism 71 is returned to the position holding state. After the position holding mechanism 71 is returned to the position holding state, the biasing force of the spring 94 causes the first holding arm 89 and the second holding arm 90 to bend to the front side and return to the swinging state.

  As shown in FIG. 8, the release operation wire 101 is provided in parallel with the horizontal link 74 in a plan view, and the transmission belt 51 as an endless rotating body for transmitting power to the drive shaft 50 is a horizontal link 74 and The space between the release operation wire 101 and the release operation wire 101 is used to pass vertically.

[Interlocking operation mechanism]
When the reaper 3 is raised to a predetermined height position (non-removal work position) or more, an interlock stop operation mechanism 109 is provided which operates the operation unit 65 to switch the feed chain clutch 49 into the disconnection state. As shown in FIG. 11, the interlocking stop operation mechanism 109 includes a swing arm 110 swinging along with the raising and lowering of the reaper 3, a push action portion 111 pressing on the clutch operation arm 69, and the swing arm 110. The interlocking operation wire 112 etc. which link with the pushing action part 111 are provided.

  The swinging arm 110 is swingably supported around a swinging axis X5 oriented in the left-right direction. The swinging arm 110 is switched to the raising position Pr and the lowering position Pd according to the raising and lowering of the reaper 3. Specifically, the swinging arm 110 is switched to the rising position Pr when the reaper 3 rises to the non-removal work position, and is switched to the lower position Pd when the reaper 3 falls to the reaping work position.

  As shown in FIG. 8, the push action portion 111 is provided at a position close to the opposite side to the side on which the command stop operation pin 84 acts in the longitudinal direction in the clutch operation arm 69. The push acting portion 111 includes a support shaft 113 fixedly supported on the side wall 6A of the threshing device 6, a boss portion 114 rotatably fitted on the support shaft 113, and a circumferential direction from an outer peripheral portion of the boss portion 114. Two arms 115 and 116 extending radially outward in a substantially L shape in plan view are provided at different positions, and a return spring 117 is provided.

  One first arm 115 of the two arms extends integrally from the boss portion 114 toward the left side. The interlocking operation wire 112 is linked to the swinging end of the first arm 115 via a stroke absorbing spring 119. The other second arm 116 of the two arms is integrally extended rearward from the boss portion 114. At the swinging end of the second arm 116, an interlocking stop operating pin 120 is provided which can be pressed by bringing the clutch operating arm 69 into contact.

  When the interlocking operation wire 112 is pulled, the first arm 115 and the second arm 116 swing around the axial center X6 of the support shaft 113 in the clockwise direction in plan view. Along with that, the interlocking stop operation pin 120 swings in the direction of pressing the clutch operation arm 69. As a result, the shifter member 68 is rotated to shift the driven shift member 60 to switch the feed chain clutch 49 to the disengaged state.

  Also in this case, as in the case of the command stop operation mechanism 66, the driven shift member 60 is switched to the blocking state, and is pressed by the braking mechanism 64 by the large biasing force of the blocking coil spring 70 to apply the braking force. Be done. By braking, it is possible to suppress the rotation of the feed chain 15 due to the inertial force and to stop it quickly.

  When the interlocking operation wire 112 is not pulled, the interlocking stop operation pin 120 is moved away from the clutch operation arm 69 by the biasing force of the return spring 117, and the clutch operation arm 69 is attached with the coil spring 63. It is returned to the in position by the force.

[Buffering mechanism]
The buffer mechanism in cooperation with the operation unit 65 in the command stop operation mechanism 66 and the interlocked stop operation mechanism 109 will be described.
A first buffer mechanism K1 linking the command stop operation mechanism 66 to the operation unit 65, and a second buffer mechanism K2 linking the interlock stop operation mechanism 109 to the operation unit 65 are provided. When one of the command stop operation mechanism 66 and the interlocked stop operation mechanism 109 performs switching to the shutoff state, the buffer mechanism K2 performs the operation force of one mechanism, the command stop operation mechanism 66 and the interlock stop operation mechanism It is configured not to be transmitted to the other mechanism 109.

  To add the description, as described above, the mechanism by which the command stop operation pin 84 in the command stop operation mechanism 66 contacts and pushes the clutch operation arm 69 in the operation unit 65 is the first buffer mechanism K1. is there. The second buffer mechanism K2 is a mechanism in which the interlocking stop operation pin 120 in the interlocking stop operation mechanism 109 is brought into contact with the clutch operation arm 69 in the operation unit 65 to push it.

  When the switching operation is performed by the interlocking stop operation mechanism 109, as shown in FIG. 10, the first buffer mechanism K1 separates the command stop operation mechanism 66 from the clutch operation arm 69 to operate the interlocking stop operation mechanism 109. The force is not transmitted to the command stop operation mechanism 66. When the switching operation is performed by the command stop operation mechanism 66, the second buffer mechanism K2 separates the interlock stop operation mechanism 109 from the clutch operation arm 69 as shown in FIG. Is not transmitted to the interlocking stop operation mechanism 109.

  The operation unit 65 is configured to switch the feed chain clutch 49 to the disengaged state by rotating the clutch operation arm 69 in a predetermined direction (left direction in FIG. 8). When the command stop operation pin 84 contacts the clutch operation arm 69 and pushes it so as to turn in a predetermined direction, the interlock stop operation pin 120 is separated from the clutch operation arm 69, so interlocking stop is performed. The operating force is not transmitted to the operating pin 120.

  When the interlocking stop operation pin 120 contacts the clutch operation arm 69 and pushes it so as to turn in a predetermined direction, the instruction stop operation pin 84 separates from the clutch operation arm 69. The operating force is not transmitted to the operating pin 84.

  Therefore, switching the feed chain clutch 49 to the disengaged state when the reaper 3 rises to a predetermined height position, and stopping the feed chain clutch 49 when operating alone, are smoothly performed separately. And it can be done quickly.

[Control configuration]
As shown in FIG. 12, an engine control unit 121 that controls the operating state of the engine 9 is provided, and the control device 43 is configured to instruct the engine control unit 121 to perform control information according to the work status. Then, when the stop switch 108 is operated by the operator while the feed chain 15 is rotated and the threshing device 6 is operating, the control device 43 performs the shutoff switching operation based on the operation of the stop switch 108. Feed chain stop processing for operating the release mechanism 73 in the mechanism 67 to stop driving the feed chain 15, engine stop processing for stopping the operation of the engine 9, threshing part raising processing for switching the upper side threshing segment 30 to the raised position Each is configured to run.

The feed chain stop processing will be described.
The control device 43 operates the shutoff motor 100 so that the second holding arm 90 moves to a preset position to release the contact restriction state with the first holding arm 89 according to the detection value of the potentiometer 102. . As a result, the release operation wire 101 is pulled, and the position holding in the position holding mechanism 71 is released, and the feed chain clutch 49 is switched to the disconnection state.

The engine stop processing will be described.
The control device 43 instructs the engine control unit 121 to perform control information for stopping the operation of the engine 9. The engine control unit 121 stops the operation of the engine 9 by processing such as, for example, stopping the fuel supply to the engine 9 by operating the fuel shutoff valve provided in the fuel supply passage.

A threshing part raising process is demonstrated.
The controller 43 controls the electric hydraulic cylinder 38 to raise the upper side threshing split body 30 by a second operation amount smaller than the first operation amount corresponding to the maintenance raising position based on the detection value of the height sensor 42. Control the operation of (see Figure 4). The maintenance elevation position can be set in a plurality of stages by the level setter 45, but the second operation amount is a small operation amount which is lower than any of the plurality of maintenance elevation positions. In the case of operation by the stop switch 108, in many cases it is possible to remove the sandwich such as grain scale or foreign matter pinched in the feed chain 15, and the second set amount is set to the amount of increase necessary to remove the sandwich. Be done. Although the raised position for maintenance is not shown, the raised position for maintenance is largely open to the extent that cleaning of the mesh 21 and the threshing drum 20 inside the throttling chamber 19 and replacement of parts can be performed.

[Another embodiment]
(1) In the above embodiment, the operating unit 65 is provided with the clutch operating arm 69 that can rotate integrally with the shifter member 68, and the first buffer mechanism K1 links the clutch operating arm 69 and the command stop operating mechanism 66. The second buffer mechanism K2 is configured to link the location different from the location to which the first buffer mechanism K1 is linked in the clutch operating arm 69 and the link stop operation mechanism 109, but instead of this configuration The feed chain clutch 49 is separately provided with a pair of operating bodies, each operating body is linked to the command stop operating mechanism 66 and the interlocked stop operating mechanism 109 separately, and One buffer mechanism K1 and a second buffer mechanism K2 may be provided.

(2) In the above embodiment, the command stop operation mechanism 66 and the interlock stop operation mechanism 109 are configured to push and move the clutch operation arm 69 in a state of contacting the clutch operation arm 69 to switch the feed chain clutch 49. For example, various configurations can be adopted, such as a configuration in which the long hole is used for the operation in the predetermined direction by the engagement between the pin and the long hole.

(3) In the above embodiment, the clutch operating arm 69 is formed in the shape of a linearly extending strip and the longitudinal middle portion is connected to the support shaft portion 68 a of the shifter member 68. Alternatively, for example, an arm having a substantially L-shape extending in different directions in the circumferential direction from the connection point to the support shaft 68a may be used.

(4) In the above embodiment, the braking mechanism 64 acting on the driven shift member 60 is used. However, the braking mechanism may not be provided.

(5) In the above embodiment, the operation unit 65 is provided with the shift fork type shifter member 68. However, instead of this configuration, for example, the clutch member is provided with the guide cam surface and slides in the radial direction. The rod may be engaged with the guide cam surface, and may be guided so as to slide in the axial direction along the cam surface as the transmission shaft rotates, and the clutch may be turned on and off.

  INDUSTRIAL APPLICABILITY The present invention can be applied to a combine having a feed chain for conveying a reaper to a threshing device and in which power to the feed chain can be interrupted by a feed chain clutch.

Reference Signs List 3 reaper 15 feed chain 49 feed chain clutch 50 transmission shaft 59, 60 clutch member 65 operation portion 64 braking mechanism 66 command stop operation mechanism 68 shifter member (operation member)
69 Clutch operating arm (arm)
109 Interlocking stop operation mechanism K1 First buffer mechanism K2 Second buffer mechanism

Claims (5)

Ascent and descent reaping section which reaps cropped rice straw,
A feed chain for transporting the reaper to the threshing device;
A feed chain clutch switchable between a transmission state for transmitting power to the feed chain and a disconnection state for cutting off the power to the feed chain;
An operating unit capable of switching between an on position corresponding to the transmission state of the feed chain clutch and a off position corresponding to the disconnection state;
A command stop operation mechanism that switches the feed chain clutch to the disengaged state by operating the operation unit based on an artificial stop command;
An interlock stop operation mechanism that operates the operation unit to switch the feed chain clutch to the disengaged state when the reaper is raised to a predetermined height position or higher;
A first buffer mechanism that links the command stop operation mechanism to the operation unit;
A second buffer mechanism linking the interlock stop operation mechanism to the operation unit;
When one of the first stop mechanism and the second stop mechanism performs switching to the shutoff state, the first buffer mechanism and the second buffer mechanism are configured to control the operating force of the one mechanism, A combine configured not to transmit to the other mechanism of the command stop operation mechanism and the interlocked stop operation mechanism. The operation unit is provided with an operation member for switching the feed chain clutch by a rotation operation, and an arm rotatable around the rotation axis of the operation member with the operation member.
The first shock absorbing mechanism links the arm and the command stop operation mechanism, and the second shock absorbing mechanism is a portion different from the portion where the first shock absorbing mechanism is linked among the arms and the interlock The combine according to claim 1, which is linked with a stop operation mechanism. The command stop operation mechanism and the interlocking stop operation mechanism are configured to push and move the arm in a state of being in contact so as to turn in a predetermined direction to switch the feed chain clutch.
The first buffer mechanism separates the command stop operation mechanism from the arm when the switching operation is performed by the interlock stop operation mechanism, and transmits the operation force of the interlock stop operation mechanism to the command stop operation mechanism. Without
When the switching operation is performed by the command stop operation mechanism, the second buffer mechanism separates the interlock stop operation mechanism from the arm, and transmits the operation force of the command stop operation mechanism to the interlock stop operation mechanism. The combine according to claim 2 which does not let it do. A transmission shaft for transmitting power to the feed chain is provided.
The feed chain clutch is of a meshing type having a pair of clutch members that can be meshed oppositely on the transmission shaft,
The combine according to any one of claims 1 to 3, wherein the operation portion is provided with a shift fork type shifter member capable of disengaging the pair of clutch members.   A braking mechanism is provided which applies a braking force to a member of the pair of clutch members moved along the transmission shaft as the operation portion is operated to the off position. The combine according to item 4.

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